KR940007480Y1 - Inertia moment regulating device for vcr head drum - Google Patents

Abstract

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Description

Variable moment of inertia of V-Cal rotating drum

1 is a front view of the BC-AL rotating drum to which the device of the present invention is applied.

Figure 2 is an exploded perspective view showing the configuration of the device of the present invention.

Figure 3 is a longitudinal sectional view showing the configuration of the device of the present invention.

5 is a plan view partially cut away to explain the operation of the device of the present invention.

(A) and (b) of FIG. 6 are explanatory diagrams for explaining the operation of the present invention, (a) shows a rotating spring mass meter, and (b) shows a free body diagram of FIG. 6 (a). .

Figure 7 is an explanatory diagram showing the moment of inertia of the rotating drum rotating part according to the present invention.

* Explanation of symbols for main parts of the drawings

1: rotor 2: stator

3: drum motor 4: rotating shaft

5: upper rotating drum 6: lower fixed drum

7: cylindrical shaft 8, 8 ': leaf spring

8a, 8'a, 10a, 10a ': fixed holes 9, 10: inner and outer inertial masses

9a, 9a ': fixing protrusion 11: screw

The present invention relates to a variable moment of inertia control device of V-Cal rotating drum, which can accommodate NTSC and PAL system at the same time without any separate design and component change, and can cope with the change of speed of rotating drum according to each shifting mode. The present invention relates to a variable moment of inertia control device of a BC-AL rotating drum which enables the moment of inertia of the rotating drum to be appropriately changed with respect to a change in the rotational speed of the rotating drum.

In a typical V-Cal, a video head is attached to both sides of the bottom of an upper rotating drum of the rotating drum, and the video head is subjected to a collision pulse while traveling in contact with the tape by the rotation of the rotating head drum driven by the drum motor. The impulse pulses are cycles of 1/60 sec and 1/50 sec, respectively, in NTSC and PAL systems with different rotational speeds of rotating drums.The frequency of such impulse pulses is 60 Hz for NTSC and 50 Hz for PAL. The natural frequency of the torsional vibration to the rotating drum should be determined in the design process to avoid the problem, and the natural frequency of the rotating drum should be determined as the area that is least affected by the high frequency component of the collision pulse.

In addition, in the above-described NTSC and PAL systems, the rotational speed of the rotating drum must be changed not only in the CUE and REV modes, which are the variable speed playback mode of the tape, but also in the high speed exploration and playback mode.

The natural frequency of the torsional vibration with respect to the rotating drum is left and right in particular by the moment of inertia of the rotating drum, so that the proper moment of inertia of the rotating drum is one of the important design points.

The theoretical basis for this is as follows.

In general, the rotating part of the rotating drum is divided into an upper rotating drum to which a video head is attached on the upper side and a rotor of a drum motor rotating the rotating shaft on the lower side.

If the natural frequency of the torsional vibration in the rotating drum as described above is f _n ,

It can be represented as.

Here, I ₁ is the moment of inertia for the upper rotating drum of the rotating drum, I ₂ is the moment of inertia for the rotor portion of the drum motor, K is a constant determined by the axis of rotation,

It can be represented as.

Where G is the shear stiffness coefficient of the rotating shaft, d is the diameter of the rotating shaft, and l represents the effective length of the rotating shaft.

Since the natural frequency f _n of the torsional vibration with respect to the rotating drum is a value determined by the moments of inertia I ₁ and I ₂ for the rotor of the upper drum and the drum motor, as in the formula (1), Rotating drum can be shared by NTSC and PAL methods with different rotational speeds of the rotating drum unless the inertia moment value of the rotating part constituting the rotating drum is changed to a rotating drum with a new inertia moment value. Not only could not be a rotating drum with an appropriate natural frequency, but also in each of the above-described schemes, due to the change in the rotational speed of the rotating drum according to the shift mode, it was difficult to cope with the proper natural frequency.

The present invention has been devised to solve the above-mentioned drawbacks, and the object of the present invention is to adjust the moment of inertia of the rotating drum variably in accordance with the rotating speed of the rotating drum, respectively It can accommodate all other NTSC and PAL methods without any change of parts, and if the rotational speed of the rotational drum is required, such as shift mode, it has appropriate moment of inertia according to it. The present invention provides a variable moment of inertia control device of a VRL rotating drum device capable of setting an optimum moment of inertia of a rotating drum by checking an image quality state according to a moment value.

The present invention having the object as described above is fixed to the rotating part of the rotating drum, that is, the rotor outer peripheral surface of the drum motor with a screw, and by molding both sides of the outer peripheral surface of the cylindrical body in a predetermined arc shape with a certain interval The opposite plate springs are bent, and the inertial masses are fixed to the outer and inner surfaces of the cylindrical plate springs, and the shape of the plate springs is changed by the centrifugal force of the inertial mass system due to the rotation of the rotating shaft. This is achieved by causing the distance from the axis of rotation of the center of mass to change, and thus the moment of inertia of the rotating drum to vary with the speed of rotation.

Hereinafter, the present invention in more detail by the accompanying drawings as follows.

As shown in FIGS. 1 to 4, a drum motor 3 composed of a rotor 1 and a stator 2, a rotating shaft 4, an upper rotating drum 5, and a lower fixed drum (6) In a rotating drum of a conventional BC-AL, the cylindrical body (7) is fixed to the outer peripheral surface of the rotor (1) of the drum motor (3) with a screw (11), and the cylindrical body (7) The outer circumferential surface of the outer circumferential surface is punched to a predetermined arc shape to bend the leaf springs (8) and (8 ') opposite to each other at a predetermined interval, and the fixing holes inside the leaf springs (8) (8') (8a) (8'a) inserts the fixing projections (9a) (9a ') of the inner inertial mass (9), and the inner inertial mass (9) protruding outward of the leaf springs (8) (8'). And fixing holes 10a and 10a 'of the external inertia mass 10 to the fixing protrusions 9a and 9a' of the ().

Referring to the operation, effects of the present invention configured as described above are as follows.

As shown in FIG. 5, when the rotating shaft 4 of the rotating drum rotates at an angular velocity of ω, the inertial masses 9 and 10 fixed to the leaf springs 8 and 8 'of the cylindrical body 7 are rotated. The centrifugal force is applied to the leaf springs 8 and 8 'to open from the imaginary line in the state shown by the solid line, and according to the speed of the rotating drum, the position of the inertial mass 9 and 10, that is, the mass of the rotating drum. It can be seen that the center is variable.

This will be described in more detail with reference to the accompanying drawings.

FIG. 6 (a) shows the operation principle of the device of the present invention with a rotating spring mass meter rotating at a rotational angular velocity (ω), where r is the center (0) of the rotating shaft (4) and the inertial mass (9) ( The distance from the center of mass P of 10), K is the spring constant of the leaf springs 8, 8 'coupled with the inner and outer inertial masses 9 and 10, and m is the inertial mass 9 The mass of () is shown respectively.

6 (b) is a free body diagram of the rotating spring mass system of FIG. 6 (a). As shown therein, the center (0) of the rotating shaft 4 and the inertial mass ( 9) The distance between the center of mass (P) of (10) is until the axis of rotation (4) When r is rotated at an angular velocity of ω, the inertia force causes the position of P to move to P 'and the leaf springs 8 and 8' are deformed by Δr. = r + Δr.

At this time, considering the balance of forces acting on the inertial masses 9 and 10, the restoring force K · Δr of the leaf springs 8 and 8 'and the centrifugal force m of the inertial masses 9 and 10 (R + Δr) ω ² ) is in equilibrium.

In other words, the equilibrium of force with respect to inertial mass m

K · Δr = m (r + Δr) ω ² ). … (3)

Is indicated by

Summarizing the above formula (3) with the shifted distance Δr of the inertial mass m,

… … (4)

Can be displayed as

The increase in moment of inertia

ΔI ₂ = I ₂ -I ₂

= m (OP ³ ) ² -m (OP) ²

= m (r + Δr) ² -mr ²

= m (Δr ² + 2rΔr)... … (5)

It can be displayed as

Here, I ₂ ′, I ₂ ′ show the moment of inertia of the portion of the rotor 1 before the rotation shaft 4 rotates and the moment of inertia of the portion of the rotor 1 during rotation. See also).

Therefore, if there is a change of moment of inertia at the rotating part of the rotating drum, the natural frequency of the torsional vibration to the rotating drum is

… … (6)

It can be expressed as.

Therefore, when Equation (4) is substituted into Equation (5), the increase amount ΔI ₂ of the moment of inertia is

… … (7)

Since the increase amount of inertia moment ΔI ₂ changes according to the rotational angular velocity (ω), the mass (m), the center of mass distance (r) of the inertial masses (9) and (10), and the leaf spring ( 8) When the spring constant K of (8 ') is properly selected, the increase amount of inertia moment (ΔI ₂ ) is adjusted according to the change of the rotational angular velocity (ω) to adjust the appropriate moment of inertia. You will get it.

The present invention as described in detail above, the inertia moment of the rotating drum rotating part is arbitrarily variable according to the change of the rotating speed of the rotating drum design of the rotating drum rotating drum in the NTSC and PAL method with different rotating speed of the rotating drum It has the effect of providing a rotating drum device with an appropriate moment of inertia without modification. In addition, when the rotational speed of a rotating drum such as a shift mode or a high speed exploration and regeneration mode changes, it changes to an appropriate moment of inertia suitable for the rotational speed. It is effective.

In addition, the moment of inertia of the rotating part, which may be different due to the machining state of the rotating part of the rotating drum and the mass deviation of the parts, can be appropriately changed by the device of the present invention, so that the screen quality and quality can be improved. There is such a remarkable effect.

Claims (2)

The cylindrical body 7 in which the circular-shaped leaf spring part 8 (8 ') was formed on both sides of the outer peripheral surface is fixed to the outer peripheral surface of the rotor 1 of the drum motor 3, and the plate of the said cylindrical body 7 is carried out. An inertia moment variable control device of a BC-AL rotating drum, characterized in that the inner and outer inertia masses (9) (10) are fixed to the inner and outer sides of the spring (8) (8 '). The fixing holes 8a and 8a 'are drilled in the leaf springs 8 and 8', and the fixing protrusions 9a and 9a 'are formed in the inner inertial mass 9. In addition, the fixing holes (10a) (10a) through the fixing holes (10a) (10a ') by fixing holes (10a) (10a') to the outer inertial mass (10). ') The moment of inertia variable adjustment device of the V-AL rotating drum, characterized in that fixed to the.